GE Phoenix A8950CC User manual

GE

Security

Phoenix Fiber Optic Communication System

A8950CC

installation instructions

11-A8950C

C

Installation Instructions

B

EFORE YOU BEGIN

1

GETTING STARTED 2

Overview 2

D

etermine Mounting Configuration 2

Installing Power Supply 2

INSTALLING THE OPTICAL TRANSCEIVER MODULE 3

Point-to-Point, Repeater, Self-Healing Ring Diagrams 4

LED Operating Status 5

INSTALLING THE DATA MODULE 6

Configuring the Data Module 6

Install Data Module 7

Connect Data Module 7

Channel Mapping 7

Connection Instructions 8

RS-232, TTL, RS-422, RS-485, Manchester/Biphase Interface 9

RS-485, Sensornet, Test Mode 9

Data Module - Channel Sequence 10

INSTALLING THE ETHERNET MODULE 11

Install Ethernet Module 11

Connect Ethernet Module 12

INSTALLING THE VIDEO MODULE 13

Install Video Input Module 13

Install Video Output Module 13

Connection Instructions 14

Video Module - Channel Sequence 15

INSTALLING THE AUDIO MODULE 16

Configuring the Audio Module 16

Audio Input Termination Diagrams 17

Audio Input/ Output Charts 18

Audio Module - Channel Sequence 19

INSTALLING THE CONTACT CLOSURE MODULE 20

Install Contact Closure Module 20

Connection Instructions 21

RJ45, Contact Input/ Contact Output Charts 22

Contact Input/ Contact Output - Channel Sequence 22

CONFIGURING THE PHOENIX FIBER OPTIC COMMUNICATION SYSTEM 23

T

urn on power and check status 23

Select the system topology

24-26

Set the node ID

26

FRONT PANEL MENU TREE AND DESCRIPTIONS 27

Main Menu Options 28-31

Menu Options: Video 31-33

Menu Options: Data 34-36

Menu Options: Ethernet 37

Menu Options: Audio 38-39

Menu Options: Contact Closure 39-41

MAIN LOCAL POWER/ MAIN LOCAL TEST/ MAIN LOCAL ABOUT 41-42

MAIN REMO

TE/ MAIN ABOUT

42-43

BL

ANK P

ANEL SPECIFICA

TIONS AND LIMITED W

ARRANT

Y

44

OPTICAL TRANSCEIVER MODULE SPECIFICATIONS 45

DATA MODULE SPECIFICATIONS 46

E

THERNET MODULE SPECIFICATIONS

47

VIDEO MODULE SPECIFICATIONS 48

AUDIO MODULE SPECIFICATIONS 49

CONT

A

CT CL

OSURE MODULE SPECIFICA

TIONS

50

CUSTOMER SUPPORT 50

Phoenix Fiber Optic Communication System

Before You Begin

Read these instructions before installing or operating this product.

Note: This installation should be made by a qualified service person and should conform to local codes.

T

his manual provides installation and operation information.

To use this document, you must have the following minimum qualifications:

• A basic knowledge of CCTV systems and components

• A basic knowledge of electrical wiring and low-voltage electrical hookups

Intended Use

Use this product only for the purpose for which it was designed; refer to the product

specification and user documentation.

Customer Support

For assistance in installing, operating, maintaining, and troubleshooting this product,

refer to this document and any other documentation provided. If you still have questions,

please contact technical support during normal business hours (Monday through Friday,

excluding holidays, between 6 a.m. and 5 p.m. Pacific Time).

GE Security

Call: 888 437-3287 (US, including Alaska and Hawaii; Puerto Rico; Canada)

Outside the toll-free area: 503 885-5700

Fax: 561 998-6224

Note: You should be at the equipment and ready with details before calling Technical Support.

Conventions Used in this Manual

Boldface or button icons highlight command entries. The following WARNING,

CAUTION, and Note statements identify potential hazards that can occur if the

equipment is handled improperly:

* WARNING:

Improper use of this equipment can cause severe bodily injury or equipment damage.

** CAUTION:

Improper use of this equipment can cause equipment damage.

Not

e:

Notes contain impor

tant information about a pr

oduct or procedure.

* This symbol indicates electrical warnings and cautions.

** This symbol indicates general warnings and cautions.

1

Overview

Installing the Phoenix chassis is a three-step process:

1. Install mounting hardware and power supplies.

2. Install modules and connect cabling.

3. Configure the system.

Determine Mounting Hardware

Mounting brackets are adjustable. Choose the best location to fit your application and

position brackets using the supplied hardware. Remove screws holding front mounting

bracket, move to top, bottom, back or front and refasten.

Installing Power Supplies

All installation should be from rear of rack unit.

To install power supply, slide power supply in slot "A" and secure with hardware. Remove

center support panel and use to cover open slot if redundant power supply is not used.

Optional Redundant Power Supply: When using the redundant power supply, remove panel

and insert second power supply in slot "B" and secure.

** CAUTION:

This product contains ESD-sensitive components. Although all precautions have been made to

reduce ESD susceptibility, use good grounding techniques when handling uninstalled modules

.

2

Getting Started

Specifications

Model A8960AC

Size

Weight

Model Part Number

Optional Redundant Power Supply

A8960AC

1.65 in. W x 3.30 in. H x 8.00 in. D (42 x 84 x 203 mm)

1.25 lb

. (5.67 g)

Electrical

• Input power: 100 V to 240 V, 60 to 50 Hz

• Current requirement: 2 A

• Power consumption: 40 W

• Protection: 250 V, 2 A fuse

Model

Slot B

Model Part Number

Activ

e f

use

Model P

ar

t Number

Spare fuse

Model

Slot A

.

Module Installation

The Optical Transceiver is the first module to be installed.

Overview

The Phoenix optical transceiver module is used to provide connectivity to the fiber

connections between nodes. The A8972FLC optical transceiver module contains a single

optical transceiver with dual LC connectors and is used as an ‘end node’ in either a point

to point, or linear system. The A8974FLC optical transceiver module features two optical

transceivers with two dual LC connectors and is used in repeating nodes within a linear

system as well as all nodes in a self-healing ring system.

Tools and materials required

The optical module is held in place with simple thumbscrews with screwdriver slots.

The only tool recommended is a small flat blade screwdriver.

Installation instructions:

1. Install optical transceiver module in slots 9 and 10 (color-keyed white) and secure.

INSERT OPTICAL TRANSCEIVER MODULES IN SLOTS 9-10 (White)

2. Connect fiber:

Connect single-mode fiber optic cables by using LC connectors. Each port connects to a

pair of fibers. The top fiber in a port is the laser output (Tx) and the bottom fiber is the

photo diode input (Rx). In a point-to-point system, connect the optic in port A from the

first node to the optic in port A in the second node. Remember that the two fibers need

to be crossed, so that the laser output on one node is connected to the photodiode

input in the other node. This can be verified by observing the corresponding LEDs as

shown in the table below.

In a linear system, connect the fiber to Optic A in the end node (node with only one

fiber transceiver) to Optic B in the subsequent node. Repeat until the ‘headend’ node

is reached, where the fiber must go into Optic A .

In self-healing ring systems, simply connect Optic A from one node to Optic B on the

next node, throughout the ring.

** CAUTION:

Use caution when inserting it into a slot adjacent to an existing module. It is best to install this

module in your node first, to avoid potential damage to components on the back of this module.

* WARNING:

Insure main power is off when installing or removing.

Installing the Optical Transceiver Module

3

Point-to-Point Connect

Repeater Connect

Self-Healing Connect

Tx A

Rx A

T

x A

Rx A

A8972FLC

A8974FLC

A8972FLC A8972FLC

Tx A

Rx A

HEAD END MIDDLE NODES

FIELD END NODE

Tx B

Rx B

Tx A

Rx A

Tx A

Rx A

A8974FLC A8974FLC A8974FLC A8974FLC

Tx A

Rx A

Tx A

Rx A

Tx A

Rx A

Tx A

Rx A

Tx B

Rx B

Tx B

Rx B

Tx B

Rx B

T

x B

Rx B

4

LED operating status

Optic LED

RED Indicates faulty LASER or no module installed

OFF LASER operating within specifications

3. Verify fiber connectivity:

Using the LEDs on the back of the unit adjacent to the optic module, verify proper

operation as shown in the table below. Both optical launch power and optical receive

power, as well as transceiver status, can be verified from the LCD front panel.

Tx

GREEN Indicates sufficient power received and frame synchronization

OFF Indicates insufficient optical power

Rx

5

Setting Mode

8 RS-485 2-wire 2 V

9 RS-485 4-wire standard

A RS-485 4-wire 1 V

B RS-485 4-wire 2 V

C Reserved

D Reserved

E Reserved

F Test Mode

Overview

The Phoenix A8910MPD data module is capable of inserting/extracting

4 channels of multiprotocol serial data (MPD) per module. With a maximum of four

cards per node, the system capacity is 16 channels. Each channel is capable of

transmitting and receiving serial data throughout the Phoenix system. The card is not

limited to any single data type so that various formats can be mixed on a single card.

As with other GE Security MPD products, data translation capabilities are included.

Tools and materials required

The data modules are held in place with simple thumbscrews with screwdriver slots.

The only tool recommended is a small flat blade screwdriver.

Installation instructions:

1. Configure data module:

Prior to installation, you must specify the appropriate data format using the rotary

switches on the module. For each channel on the data module, rotate the dial switch to

the desired format. If you want to select the data format from the front panel, leave the

switch in position 0.

Setting Mode

0 Softw

are-selectable (factory preset)

1 RS-232 (3-wire)

2 RS-232 + handshake

3 TTL

4 RS-422 2-wire

5 Manchester/biphase

6 RS-485 2-wire standard/Sensornet

7 RS-485 2-wire 1V

NOTE: The DATA SELECT switches are shipped in the Software-Selectable setting.

As with all GE Security MPD products, data translation can easily

be accomplished using the table information below.

Translation

Comment

Input

TTL RS-232, 3-wire

TTL RS-422

RS-232, 3-wire TTL

3

4

2

7 - A

1

Signal level conversion.

Single ended to differential conversion.

Single ended to differ

ential conv

ersion.

Differential to single ended conversion.

Differ

ential to single ended conv

er

sion.

RS232 Handshaking bit is used to indicate Tri-state.

Tri-state detection circuitry activates handshaking bit.

Output

1

3

1

7 - A

2

4

3

RS-422 TTL-wire

RS-422 RS-232, 3-wire

RS-485 RS-232, 5-wire

RS-232, 5-wire RS-485

RS-232, 3-wir

e RS-422

Installing the Data Module

6

2. Install data module:

Up to four data modules can be installed in the Phoenix node.

From left, locate and insert data modules into slot 1, 2, 3, or 4

(color-keyed red) and secure.

3. Connect:

Each data module is shipped with (four) RJ45 cables and (four) breakout boxes to aid in

connecting to the Phoenix. Use the tables below to determine pinout information for

your application. GE Security recommends using shielded cable for all single ended

applications and twisted shielded cable for all differential formats. Wire gauge is

dependent on copper run length. Refer to manufacturer of data equipment for

specific recommendations. Once the data equipment has been connected, confirmation

of data activity can be verified on the front panel LCD.

The channel order is sequential, beginning with the top RJ45 in slot 1 as Channel 1,

working vertically such that the bottom RJ45 in slot 1 is Channel 4, and the top RJ45 in

slot 2 is Channel 5. This continues to the bottom RJ45 in slot 4, which is mapped to

Channel 16.

INSERT DATA CARDS IN SLOTS 1-4 (Red)

7

D

ATA EQUIPMENT

F

IBER LINK

1 8

DATA OUT

DATA IN

DATA OUT

F

igure 1. Fiber Link Data Connections

Figure 1. Terminal Block Pin Assignments

Figure 2. RJ45 Socket

(Viewed from the rear of the unit)

8

7

6

5

4

3

2

1

Using the breakout box

A breakout box with a 3’ CAT 5 patch cord

(supplied) can be used to interface to the

Phoenix system. Pinouts are shown in the

tables and figures above.

RJ45-A

RJ45-B

RJ45-C

RJ45-D

8

1 8

NOTE: When making data connections listed in Tables 3 through 11, always connect the pins labeled IN

on the fiber unit to the pins labeled OUT on the external equipment, and the pins labeled IN on the

external equipment to the pins labeled OUT on the fiber unit.

TABLE 3: RS-232 INTERFACE

D

ATA SELECT Switch: Position 1

Signal

1

RS-232 Out

RS-232 In

N/C

RTS/CTS Out

RTS/CTS In

GND/SHIELD

GND

RS-422 Out (+)

RS-422 In (+)

N/C

Termination, tie to 8 if req’d.

RS-422 Out (-)

RS-422 In (-)

GND/SHIELD

N/C

RS-485 (+)

+5 VDC Bias Out

Termination, tie to 8 if req’d.

N/C

RS-485 (-)

GND

GND/SHIELD

GND

GND/SHIELD

N/C

TTL Out

TTL In

Tie to pin 6

N/C

Manchester/Biphase Out (-)

GND/SHIELD

Manchester/Biphase Out (+)

N/C

Manchester/Biphase In (-)

Manchester/Biphase In (+)

N/C

T

ermination, tie to 8 if req’d.

4

6

7

8

5

3

2

TABLE 5: TTL INTERFACE

DATA SELECT Switch: Position 3

Signal

1

4

6

7

8

5

3

2

TABLE 6: RS-422 INTERFACE

DATA SELECT Switch: Position 4

Signal

1

4

6

7

8

5

3

2

TABLE 7: MANCHESTER/BIPHASE INTERFACE

DATA SELECT Switch: Position 5

Signal

1

4

6

7

8

5

3

2

T

ABLE 8: RS-485 2-WIRE INTERFACE

DATA SELECT Switch: Position 6 (<200mV),

P

osition 7 (<1V), P

osition 8 (<2V)

Signal

1

4

6

7

8

5

3

2

T

ABLE 4: RS-232 WITH HANDSHAKING INTERFACE

DATA SELECT Switch: Position 2

Signal

1

4

6

7

8

5

3

2

9

TABLE 9: RS-485 4-WIRE INTERFACE

DATA SELECT Switch SW1:

P

osition 9 = standard offset

P

osition A = 1V offset

Position B = 2V offset

Signal

1

4

6

7

8

5

3

2

TABLE 10: SENSORNET INTERFACE

DATA SELECT Switch: Position 6

Signal

1

4

6

7

8

5

3

2

TABLE 11: TEST MODE LOOPBACK INTERFACE

DATA SELECT Switch: Position F

Signal

1

4

6

7

8

5

3

2

RS-485 Out (+)

RS-485 In (+)

+5 VDC Bias Out

Termination, tie to 8 if req’d.

RS-485 Out (-)

RS-485 In (-)

GND/SHIELD

Tie to pin 8

Tie to pin 1

N/C

Tie to pin 7

Tie to pin 2

N/C

Sensornet (+)

N/C

Termination, tie to 8 if req’d.

N/C

Sensornet (-)

GND

GND/SHIELD

Data module - channel sequence

Slot 1

RJ45-A Ch 1 IN/OUT

RJ45-B

Ch 2 IN/OUT

RJ45-C Ch 3 IN/OUT

RJ45-D Ch 4 IN/OUT

Slot 4

Ch 13 IN/OUT

Ch 14 IN/OUT

Ch 15 IN/OUT

Ch 16 IN/OUT

Slot 3

Ch 9 IN/OUT

Ch 10 IN/OUT

Ch 11 IN/OUT

Ch 12 IN/OUT

Slot 2

Ch 5 IN/OUT

Ch 6 IN/OUT

Ch 7 IN/OUT

Ch 8 IN/OUT

10

Overview

The Phoenix A8911ETH Ethernet module provides Ethernet connectivity to the Phoenix

system. Each module has three RJ-45 ports supporting full-duplex 10/100Base-T interfaces.

Each port also supports Auto-Negotiation and automatic MDI/MDI-X selection.

Unlike other modules used in the Phoenix system, the ethernet module does not use “chan-

nels”. Each slot position provides access to one of four independent Ethernet

networks. Every port on a module can communicate with every other port on other

modules connected to the same network (i.e. modules plugged into the same slot number

at different nodes). There is no restriction to the number of modules connected to a

network, however they must share bandwidth between nodes. Each network can sustain

25Mbps throughput between nodes.

Note: Ethernet is inherently a bi-directional communication protocol. Therefore all nodes in

a Phoenix system with Ethernet modules must be connected with duplex fiber connections.

Simplex connections between nodes will cause the network to fail.

Tools and materials required

The Ethernet modules are held in place with simple thumbscrews with screwdriver slots.

The only tool r

ecommended is a small flat blade screwdriver.

Installation instructions:

1. Install the Ethernet module:

Up to four Ethernet modules can be installed in the Phoenix node. From left, locate and

insert Ethernet modules into slot 1, 2, 3, or 4 (color-keyed red) and secure.

INSERT ETHERNET MODULES IN SLOTS 1-4 (Red)

Installing the Ethernet Module

11

2. Connect:

Connect Ethernet-capable equipment directly to the Ethernet module using CAT5 twisted-

pair cables with male RJ-45 connectors at both ends. Do not use breakout boxes.

Standard CAT5 cabling used for Ethernet is available with either straight-through or

crossover connections. Either variety may be used with the Ethernet module. The

auto-MDI/MDI-X feature of each port automatically detects the type of cable

connection to establish link.

3. Configure:

At power-up, every port has Auto-Negotiation enabled. This should work seamlessly

with most Ethernet equipment. However, if necessary, Auto-Negotiation, Link Speed

and Duplex can be configured manually via the Phoenix chassis’s front panel.

Refer to the section Front Panel Menu Tree and Descriptions for more information.

12

Overview

The Phoenix A8900VI input module is capable of inserting up to four baseband,

composite video signals per card. A maximum of four cards can be installed in any node,

allowing up to 16 inputs per node.

The Phoenix A8905VO output module is capable of outputting up to 4 base band, composite

video signals per card. A maximum of four cards can be installed in any node, allowing up

to 16 outputs per node.

Tools and materials required

The video modules are held in place with simple thumbscrews with screwdriver slots.

The only tool recommended is a small flat blade screwdriver.

Installation instructions:

1. Install video input module:

As shown below, install video Input modules in slots 5, 6, 7, or 8 (color-keyed green)

and secure. Up to four modules may be installed per Phoenix node. Up to four incoming

video signals can be installed per module by connecting to BNC mounts (four) on each card.

INSERT VIDEO INPUT MODULES IN SLOTS 5-8 (Green)

INSERT VIDEO OUTPUT MODULES IN SLOTS 11-14 (Blue)

2. Install video output module:

As shown below, install video output modules in slots 11, 12, 13, or 14 (color-keyed blue)

and secure. Up to four modules may be installed per Phoenix node. Up to four outgoing

video signals for monitoring or recording can be installed per module by connecting to

BNC mounts (four) on each card.

Installing the Video Module

13

Connection instructions

Video Inputs:

Connect video source equipment such as cameras or matrix switcher outputs to the

video input modules using the BNCs on the back of the panel. Confirmation of video

presence can be confirmed on the front panel LCD. The channel order is sequential,

beginning with the top BNC in slot 5 as Channel 1, working vertically such that the

bottom BNC in slot 5 is assigned Channel 4, and the top BNC in slot 6 is

assigned Channel 5. This continues to the bottom BNC in slot 8, which is mapped

to Channel 16.

Video Outputs:

Connect video monitoring equipment including monitors and recording devices, to

the video output cards using the BNCs on the back of the panel. Confirmation of video

output can be confirmed on the front panel LCD. As with the inputs cards, the channel

order is sequential, beginning with the top BNC in slot 11 as Channel 1, working vertically

such that the bottom BNC in slot 11 is assigned Channel 4, and the top BNC in slot 12 is

assigned Channel 5. This continues to the bottom BNC in slot 14, which is Channel 16.

14

Video Input module - channel sequence

S

lot 5

BNC A Ch 1 IN

BNC B Ch 2 IN

BNC C Ch 3 IN

BNC D Ch 4 IN

Slot 8

Ch 13 IN

Ch 14 IN

Ch 15 IN

Ch 16 IN

Slot 7

Ch 9 IN

Ch 10 IN

Ch 11 IN

Ch 12 IN

Slot 6

Ch 5 IN

Ch 6 IN

Ch 7 IN

Ch 8 IN

Video Output module - channel sequence

Slot 11

BNC A Ch 1 OUT

BNC B Ch 2 OUT

BNC C Ch 3 OUT

BNC D Ch 4 OUT

Slot 14

Ch 13 OUT

Ch 14 OUT

Ch 15 OUT

Ch 16 OUT

Slot 13

Ch 9 OUT

Ch 10 OUT

Ch 11 OUT

Ch 12 OUT

Slot 12

Ch 5 OUT

Ch 6 OUT

Ch 7 OUT

Ch 8 OUT

BNC A

BNC B

BNC C

BNC D

15

Overview

The Phoenix A8920A audio module is capable of inputting and outputting up to 4 audio

channels. The audio module occupies one audio slot (color coded black) and with up to

four slots available, each node has a capacity of 16 channels. The audio interface

connector is four, ganged RJ45 connectors located on each card. The audio module

supports an audio test pattern, similar to GE Security standards.

Tools and materials required

The audio modules are held in place with simple thumbscrews with screwdriver slots.

The only tool recommended is a small flat blade screwdriver.

Installation instructions:

1. Configure audio module:

Prior to installation, the audio modules need to be configured for proper

use in the system. Refer to the Fig. 1 and Fig. 2 for switch locations and settings.

a. Input termination: Input termination should be set depending on your system

requirements. You can choose either high-impedance (default) or 600 ohm

termination on an individual channel basis.

b. Input range: Based on the level of input signal you will be applying the

specific channel, you may choose to modify the input range selection switches.

By default, the switches are set to high range (+18dBu) and will transmit any

audio signal within the specifications of the unit. If lower level input signals are

expected, you may change the input range to low (+8dBu) to increase the overall

signal to noise ratio. Clipping (distortion) however, will occur if input levels exceed

+8dBu. Note that for each channel, two switches must be thrown to change

the input range.

c. Output range: To normalize the system, you must switch the output range

switch to the same setting as the CORRESPONDING input range switch. Note, this

does not mean that the switches on the same board need to be the same, just

that the switches at the input node, must match the switches at the output node.

If multiple outputs are mapped (broadcast mode) than all outputs must be set to

the same gain range.

AUDIO OUTPUT

RANGE

A

UDIO INPUT

TERMINATION

Figure 1. Audio Level Switch Locations

AUDIO INPUT

RANGE

Installing the Audio Module

16

2. Installing audio modules:

Audio modules must be installed in slots 15, 16, 17, or 18 (color coded black).

Up to four Audio modules can be installed per Phoenix node.

The channel sequence is as follows:

Slot 15, top RJ45 connector is assigned to Channel Inputs 1 and 2.

The second RJ45 connector gets assigned to Channel Inputs 3 and 4.

The third RJ45 connector gets assigned to Channel Outputs 1 and 2.

The bottom RJ45 connector gets assigned to Channel Outputs 3 and 4.

Subsequent modules, placed in slots 16, 17, and 18 are assigned

to Channels 5-8, 9-12, and 13-16 respectively.

If a low audio level causes the output

audio signal to degrade, the input

sensitivity of the A8920A can be

increased by switching to the 8 dBu

maximum scale.

You can set the transmitter input to

8 dBu and the receiver output to 18

dBu to add 10 dB of gain to the

system, however, this also increases

system signal-to-noise ratio (S/N).

AUDIO INPUT RANGE

Ch A

Ch B

Ch C

Low

High

O

N

S3

Low

High

ON

S4

AUDIO OUTPUT RANGE

Ch A

Ch B

Low

High

O

N

S7

Ch C

Ch D

Low

High

ON

S8

Low

High

ON

S5

Low

High

ON

S6

Note: Two switches per channel

Note: One switch per channel

AUDIO INPUT TERMINATION

Ch A

Ch B

High Z

600Ω

O

N

S1

Ch C

Ch D

High Z

600Ω

ON

S2

Note: One switch per channel

Figure 2. Audio Level Switch Positions

The A8920A units are shipped

with the input impedance set

at (high-Z). To select a 600Ω

input impedance in place of the

high-Z input, set switches SW1

and SW2 on the audio to 600Ω.

17

INSERT AUDIO CARDS IN SLOTS 15-18 (Black)

3. Connecting to audio modules:

GE Security recommends connecting to the terminal block using high-quality shielded,

twisted-pair wire for best audio performance.

The I/O for the audio inputs and outputs are as follows:

RJ45 - A (Top) AUDIO INPUTS - CHANNELS A-B

Audio Signal

1

IN A (+)

IN B (-)

IN A (-)

GND/SHIELD

IN B (+)

GND

4

6

7

8

5

3

2

RJ45 - C AUDIO OUTPUTS - CHANNELS A-B

Audio Signal

1

OUT A (+)

OUT B (-)

OUT A (-)

GND/SHIELD

OUT B (+)

GND

4

6

7

8

5

3

2

RJ45 - D (Bottom) AUDIO OUTPUTS - CHANNELS C-D

Audio Signal

1

OUT C (+)

OUT D (-)

OUT C (-)

GND/SHIELD

OUT D (+)

GND

4

6

7

8

5

3

2

RJ45 - B AUDIO INPUTS - CHANNELS C-D

Audio Signal

1

IN C (+)

IN D (-)

IN C (-)

GND/SHIELD

IN D (+)

GND

4

6

7

8

5

3

2

18

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